Eosin interaction of alpha-synuclein leading to protein self-oligomerization.
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Among various dyes including congo red, thioflavin S, thioflavin T, eosin, rhodamine 6G, and phenol red, the eosin was the only dye that induced self-oligomerization of alpha-synuclein in the presence of a chemical coupling reagent of N-(ethoxycarbonyl)-2-ethoxy-1, 2-dihydroquinoline. To analyze chemical nature of the eosin interaction with alpha-synuclein, the phenomenon of self-oligomerization was further examined with eosin congeners such as ethyl eosin, eosin B, phloxine B, erythrosin B, and rose bengal. The followings are the conclusions we have reached. First of all, intactness of the benzoate moiety of eosin and the negative charge on the carboxylic group of the dye are important factors leading to the specific interaction with alpha-synuclein. Secondly, the localized negative charge on the xanthene moiety of eosin is another critical factor for the interaction. As far as substituting halides are concerned, bromides and iodides on the xanthene moiety of the dyes do not make any difference on the alpha-synuclein interaction because both eosin and erythrosin B have induced the common phenomenon of self-oligomerization. The binding curve between eosin and alpha-synuclein was sigmoidal as the dye concentrations were increased. A double reciprocal plot of the saturation curve showed that the maximum number of eosin binding sites on alpha-synuclein was 1.85 with a dissociation constant of 390 microM. The dye binding to the protein appeared to occur via a positive cooperativity. The eosin binding site(s) was suggested to be located predominantly on the NAC region and partly related to the acidic C-terminus of alpha-synuclein. It has been, therefore, expected that this information might be useful to develop alpha-synuclein interactive molecules, which could provide eventual preventive or possible therapeutic means against various alpha-synuclein related disorders including Parkinson's disease. (+info)
Potent stimulation and inhibition of the CFTR Cl(-) current by phloxine B.
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The effects of the fluoresceine derivative, phloxine B, on the Cl(-) current through the cystic fibrosis transmembrane conductance regulator (CFTR) were examined in Xenopus oocytes expressing human CFTR. In whole oocytes, the CFTR Cl(-) current (I(CFTR)) was activated by superfusion with isobutylmethylxanthine and forskolin. I(CFTR) was stable during activation and deactivated rapidly upon washout of the activation solution. Phloxine B slowed deactivation and, at high concentrations, inhibited I(CFTR) weakly. In excised inside-out macropatches, I(CFTR) was activated by the catalytic subunit of protein kinase A (cPKA) and MgATP. Phloxine B (0.01 - 3 microM), applied after activation, increased I(CFTR) within 30 s followed by a slow decrease which became dominant at high concentrations. Slowing of deactivation of the CFTR was observed at all concentrations. The effect of phloxine B after 30 s had a bell-shaped concentration-dependence with midpoints at 45 and 1600 nM for the stimulatory and the inhibitory limb, respectively; maximum stimulation was about 1.8 times. The slow inhibitory component, measured after 6 min, occurred with an IC(50) value of approximately 1 microM. In the absence of cPKA, phloxine B did not stimulate I(CFTR). In the presence of cPKA and MgATP, the effects of phloxine B were more prominent at low (0.02 mM) than at high ATP (2 mM). The data show that phloxine B modulates I(CFTR) by increasing channel activity and slowing channel deactivation; at high concentrations inhibition dominates. The effects may be mediated by direct interactions with CFTR from the inside of the cell. (+info)
Novel use of bovine zeta-crystallin as a conformational DNA probe to characterize a phase transition zone and terminally differentiating fiber cells in the adult canine ocular lens.
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Using a novel immunocytochemical staining method, we aimed to characterize the phase transition zone (PTZ) (approximatly 100 microm) in adult ocular lenses and the process of terminal differentiation (denucleation) within normal fiber cells. The binding to DNA of zeta-(zeta) crystallin (Z-DNA-binding protein) and anti-double-stranded (ds-)-B-DNA antibody probes was found to decline gradually throughout denucleating fibers, with a precipitous decrease occurring at about 100 microm (PTZ). Nuclei of superficial fiber cells (in front of the PTZ) showed the highest DNA probe-binding values, followed by middle fibers (MF) and deep fibers (DF). With the use of zeta-crystallin, anti-ds-B-DNA antibody, and anti-single stranded (ss-) DNA antibody probes, it was possible to reveal a loss of reactivity of fiber cell ds-DNA. Ss-DNA antibody binding was seen initially in the MF and reached its highest intensity level in the DF. The pattern of zeta-crystallin probe-DNA reactivity correlates with the loss of anti-B-DNA antibody staining and decreased eosin-protein staining. These data suggest that a reorganization of DNA and intracellular protein supramolecular order in normal adult lenses occurs at a depth of about 100 microm (PTZ). (+info)
Phloxine B interacts with the cystic fibrosis transmembrane conductance regulator at multiple sites to modulate channel activity.
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The fluorescein derivative phloxine B is a potent modulator of the cystic fibrosis transmembrane conductance regulator (CFTR). Low micromolar concentrations of phloxine B stimulate CFTR Cl(-) currents, whereas higher concentrations of the drug inhibit CFTR. In this study, we investigated the mechanism of action of phloxine B. Phloxine B (1 microm) stimulated wild-type CFTR and the most common cystic fibrosis mutation, DeltaF508, by increasing the open probability of phosphorylated CFTR Cl(-) channels. At each concentration of ATP tested, the drug slowed the rate of channel closure without altering the opening rate. Based on the effects of fluorescein derivatives on transport ATPases, these data suggest that phloxine B might stimulate CFTR by binding to the ATP-binding site of the second nucleotide-binding domain (NBD2) to slow the dissociation of ATP from NBD1. Channel block by phloxine B (40 microm) was voltage-dependent, enhanced when external Cl(-) concentration was reduced and unaffected by ATP (5 mm), suggesting that phloxine B inhibits CFTR by occluding the pore. We conclude that phloxine B interacts directly with CFTR at multiple sites to modulate channel activity. It or related agents might be of value in the development of new treatments for diseases caused by the malfunction of CFTR. (+info)
In vitro antibacterial activities of phloxine B and other halogenated fluoresceins against methicillin-resistant Staphylococcus aureus.
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Fluorescein dyes in which the benzoic acid moiety has been tetrachlorinated (50 to 100 micro g/ml) inhibit in vitro Staphylococcus aureus growth (MIC, 25 micro g/ml). Specifically, under standard room illumination, phloxine B at a concentration of 100 micro g/ml killed 99% of the cultures (mid-log phase). It also reduced S. aureus CFU by 10(4). Structure-activity analysis revealed that the activity against S. aureus increases with the increase in the number of the substituting halogens in the hydroxyxanthene moiety. (+info)
A molecular docking strategy identifies Eosin B as a non-active site inhibitor of protozoal bifunctional thymidylate synthase-dihydrofolate reductase.
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Protozoal parasites are unusual in that their thymidylate synthase (TS) and dihydrofolate reductase (DHFR) enzymes exist on a single polypeptide. In an effort to probe the possibility of substrate channeling between the TS and DHFR active sites and to identify inhibitors specific for bifunctional TS-DHFR, we used molecular docking to screen for inhibitors targeting the shallow groove connecting the two active sites. Eosin B is a 100 microm non-active site inhibitor of Leishmania major TS-DHFR identified by molecular docking. Eosin B slows both the TS and DHFR reaction rates. When Arg-283, a key residue to which eosin B is predicted to bind, is mutated to glutamate, however, eosin B only minimally inhibits the TS-DHFR reaction. Additionally, eosin B was found to be a 180 microm inhibitor of Toxoplasma gondii in both biochemical and cell culture assays. (+info)
Activation and inhibition of ATP-sensitive K+ channels by fluorescein derivatives.
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Fluorescein derivatives are known to bind to nucleotide-binding sites on transport ATPases. In this study, they have been used as ligands to nucleotide-binding sites on ATP-sensitive K+ channels in insulinoma cells. Their effect on channel activity has been studied using 86Rb+ efflux and patch-clamp techniques. Fluorescein derivatives have two opposite effects. First, like ATP, they can inhibit active ATP-sensitive K+ channels. Second, they are able to reactivate ATP-sensitive K+ channels subjected to inactivation or "run-down" in the absence of cytoplasmic ATP. Therefore reactivation of the inactivated ATP-sensitive K+ channel clearly does not require channel phosphorylation as is commonly believed. The results indicate the existence of two binding sites for nucleotides, one activator site and one inhibitor site. Irreversible binding at either the inhibitor or the activator site on the channel was obtained with eosin-5-maleimide, resulting in irreversible inhibition or activation of the ATP-sensitive K+ channel respectively. The irreversibly activated channel could still be inhibited by 2 mM ATP. After activation by fluorescein derivatives, ATP-sensitive K+ channels become resistant to the classical blocker of this channel, the sulfonylurea glibenclamide. Negative allosteric interactions between fluorescein/nucleotide receptors and sulfonylurea-binding sites were suggested by results obtained in [3H]glibenclamide-binding experiments. (+info)
Four-week oral toxicity study of 1-carboxy-5,7-dibromo-6-hydroxy-2,3,4-trichloroxanthone (HXCA), an impurity of Phloxine B, in F344 rats.
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This study was designed to evaluate and characterize any subacute toxicity of 1-carboxy-5,7-dibromo-6-hydroxy-2,3,4-trichloroxanthone (HXCA), an impurity of Phloxine B (Food Red No. 104 in Japan, D&C Red No. 28 in the USA), when administered to both sexes of F344 rats at dietary levels of 0 (control), 0.005, 0.05 and 0.5%. During the study, the treatment had no effects on clinical signs, survival, urinalysis or ophthalmology. Hematology, blood biochemistry, gross pathology, organ weights, organ to body weight ratios and histopathology exhibited no differences of toxicological significance between control and treated rats. Reactions to treatment may be summarized as follows: there was a tendency for increased food and water consumption and decreased food efficiency in both sexes of the 0.5% group. Thus, these results indicated the no-observed-adverse-effect level (NOAEL) of HXCA to be 0.05% (39.3 mg/kg/day for males, and 41.0 mg/kg/day for females). (+info)